Free loop space homology of highly connected manifolds

Berglund, Alexander; Börjeson, Kaj

doi:10.1515/forum-2015-0074

Cited by 14 publications

(31 citation statements)

References 43 publications

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“…Definition 6.2. The convolution algebra structure on Hom(W, H) uses the coproduct structure on the domain and the product on the range to obtain an associative product of degree 1 [4]. For f, g : W → H, we have the composition Proof.…”

Section: Non-formality and Hochschild Cohomologymentioning

confidence: 99%

Non-Formality of Planar Configuration Spaces in Characteristic 2

Salvatore

2018

International Mathematics Research Notices

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We prove that the ordered configuration space of 4 or more points in the plane has a non-formal singular cochain algebra in characteristic two. This is proved by constructing an explicit non trivial obstruction class in the Hochschild cohomology of the cohomology ring of the configuration space, by means of the Barratt-Eccles-Smith simplicial model. We also show that if the number of points does not exceed its dimension, then an euclidean configuration space is intrinsically formal over any ring. *

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Section: Non-formality and Hochschild Cohomologymentioning

confidence: 99%

Non-Formality of Planar Configuration Spaces in Characteristic 2

Salvatore

2018

International Mathematics Research Notices

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“…map onto the generators on H n (Q) and H n+1 (Q) respectively. We easily compute as in [8] H * (ΩQ) ∼ = Z[u, v] with |u| = n − 1 and |v| = n so that the map Ωλ : ΩS n → ΩQ sends the generator in H n−1 (ΩS n ) to u, and the map Ωλ ′ : ΩS n+1 → ΩQ sends the generator in H n (ΩS n+1 ) to v. The composite…”

Section: Loop Space Decompositionsmentioning

confidence: 99%

“…M (t) is the generating series for ΩM [22, Theorem 3.5.1], from the fact that H * (ΩM ; D M ) is Koszul as an associative algebra[8]. Let η m := coefficient of t m in log(q M (t)).…”

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confidence: 99%

The Homotopy Type of the Loops on $$(n-1)$$ -Connected $$(2n+1)$$ -Manifolds

Basu

2019

Trends in Mathematics

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For n ≥ 2 we compute the homotopy groups of (n − 1)-connected closed manifolds of dimension (2n + 1). Away from the finite set of primes dividing the order of the torsion subgroup in homology, the p-local homotopy groups of M are determined by the rank of the free Abelian part of the homology. Moreover, we show that these p-local homotopy groups can be expressed as a direct sum of p-local homotopy groups of spheres. The integral homotopy type of the loop space is also computed and shown to depend only on the rank of the free Abelian part and the torsion subgroup.2010 Mathematics Subject Classification. Primary : 55P35, 55Q52 ; secondary : 16S37, 57N15.

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“…Berglund and Borjeson [6] have subsequently computed the free loop space homology of highly connected manifolds (including the ones considered in this paper) using different techniques. They also give a description of the action of the BV-operator and the Chas-Sullivan loop product.…”

Section: Where [M] ∈ K Is Identified With ( I≤ J C I J a I A J ) ∈ S(a)mentioning

confidence: 99%